Cell lineage of the prototroch of Patella vulgata (Gastropoda, Mollusca)

The trochophore larva of the archaeogastropod mollusc Patella vulgata has a well-developed locomotory organ, the ciliated prototroch. This structure is formed from specific founder cells, the trochoblasts. Two methods were employed to determine the composition and cell lineage of the prototroch. Fluorescent cell-lineage tracer injection in trochoblasts and trochoblast founder cells was used to show how the various trochoblasts became incorporated into the prototroch. Scanning electron microscopy was used to study both differentiation, more specifically ciliation, of trochoblasts and localization of trochoblasts in the prototroch. The results obtained with both methods are in accordance with each other. During early development all trochoblasts involved in prototroch formation become cell cycle-arrested and develop cilia. Subsequently, the trochoblasts shift in position to form a circular prototroch and a number of trochoblasts deciliate. As a result of these processes the mature prototroch consists of a number of heavily ciliated cells as well as a number of deciliated cells. Comparison of prototrochs from a number of spiralian species shows that this structure is very conserved during evolution. The significance of this is discussed.     

Dacapo, a cyclin-dependent kinase inhibitor, stops cell proliferation during Drosophila development

Most cell types in multicellular eukaryotes exit from the mitotic cell cycle before terminal differentiation. We show that the dacapo gene is required to arrest the epidermal cell proliferation at the correct developmental stage during Drosophila embryogenesis. dacapo encodes an inhibitor of cyclin E/cdk2 complexes with similarity to the vertebrate Cip/Kip inhibitors. dacapo is transiently expressed beginning late in the G2 phase preceding the terminal division (mitosis 16). Mutants unable to express the inhibitor fail to arrest cell proliferation after mitosis 16 and progress through an extra division cycle. Conversely, premature dacapo expression in transgenic embryos results in a precocious G1 arrest.     

Markers of cell polarity during and after nitrogen starvation in Schizosaccharomyces pombe

In Schizosaccharomyces pombe, nitrogen starvation induces transient acceleration of cell division and reduction in cell size with a final arrest in G1. The division size control appears to be impaired by mutations in cdr1/nim1 and cdr2, genes that encode protein kinases mediating nutritional control over the mitotic cycle. cdr- cells arrest after fewer rounds of division and are larger than the wild type. Recent work suggests that long-term nitrogen starvation causes S. pombe wild-type cells to become spherical, which suggests loss of cell polarity. cdr mutants retain the elongated shape, indicating a potential difference in cell polarity control relative to the wild type. We examined several markers related to maintenance of cell polarity in S. pombe following nitrogen starvation including cell division scar pattern and actin and microtubule cytoskeleton. Wild-type cells as well as cdr mutants maintained a normal cell division scar pattern throughout nitrogen starvation but cells dividing under these conditions developed a wall malformation in the center of the septum. In cells arrested by nitrogen starvation, actin patches, normally associated with sites of cell wall deposition, were larger and distributed randomly along the cell surface. Cytoplasmic arrays of microtubules, which are thought to be involved in control of the polarity signal, were not visibly affected. The effects were similar in wild-type cells and in cdr- mutants. Upon refeeding, the new growth always reoccurred at the tip zones and there were only small deviations of its direction from the original axis. The results indicate that cell polarity is preserved both in wild-type cells, which arrest in G1 and appear spherical, and in cdr1/nim1 and cdr2 mutants, which arrest in G2 and appear polarized throughout the starvation period.     

Role of baculovirus IE2 and its RING finger in cell cycle arrest

The ie2 gene of Autographa californica nuclear polyhedrosis virus (AcMNPV) is known to transactivate transient expression from viral promoters in a host cell-specific manner. We report that transfection of Spodoptera frugiperda (SF-21) cells with ie2 was sufficient to arrest the cell cycle, resulting in the accumulation of enlarged cells with abnormally high DNA contents. By 72 h posttransfection, more than 50% of ie2-transfected cells had DNA contents greater than 4N. There was no evidence of mitotic spindle formation in these cells, and expression of ie2 appeared to block cell cycle progression in S phase. Several ie2 mutants were analyzed to further define the region of IE2 responsible for arresting the cell cycle. Analysis of these mutants showed that deletion of the RING finger motif eliminated the ability of IE2 to arrest the cell cycle but did not affect its ability to transactivate the ie1 promoter. Moreover, mutation of a single conserved cysteine (C251) of the RING finger motif abolished the ability of IE2 to block cell cycle progression but had no apparent effect on its transregulatory activity. In contrast, a mutant of IE2 containing a deletion of residues 94 to 173 was able to block cell division but lacked trans-regulatory activity. Thus, the ability of IE2 to arrest the cell cycle depended on the integrity of the RING finger motif and was distinct from and independent of its ability to trans-activate the ie1 promoter. IE2 also arrested the division of cells derived from other insect species, Trichoplusia ni (TN-368 and BTI-TN-5B1-4) and Helicoverpa zea (Hz-AM1).     

The mechanism of Golgi segregation during mitosis is cell type-specific

Golgi membranes in Drosophila embryos and tissue culture cells are found as discrete units dispersed in the cytoplasm. We provide evidence that Golgi membranes do not undergo any dramatic change in their organization during the rapid mitotic divisions of the nuclei in the syncitial embryo or during cell division postcellularization. By contrast, in Drosophila tissue culture cells, the Golgi membranes undergo complete fragmentation during mitosis. Our studies show that the mechanism of Golgi partitioning during cell division is cell type-specific.     

Adaptation after small bowel resection is attenuated by sialoadenectomy: the role for endogenous epidermal growth factor

Reactive oxygen species generated during the metabolism of the antitumor quinone 3,6-diaziridinyl-1,4-benzoquinone (DZQ) in human colonic carcinoma HCT116 cells lead to the induction of p21 (WAF1, Cip1, or sdi1), an upstream regulator of the retinoblastoma gene product pRb involved G1 cell cycle control. We here demonstrate that the cell cycle was arrested in G2/M phase following supplementation with DZQ of human osteosarcoma Saos-2 cells (lacking both p53 and pRb) and HCT116 cells. DZQ also induced p21 and apoptosis in Saos-2 cells. The transfection of the Rb gene into Saos-2 cells did not alter the level of p21 induction, but changed cell cycle arrest into G1 phase and prevented apoptosis. These findings suggest that quinones may lead to a p53-independent and pRb-preventable G2/M arrest and apoptosis, which correlate with p21 induction.     

The lurcher mutation and ionotropic glutamate receptors: contributions to programmed neuronal death in vivo

Differentiation of trophoblast giant cells in the rodent placenta is accompanied by exit from the mitotic cell cycle and onset of endoreduplication. Commitment to giant cell differentiation is under developmental control, involving down-regulation of Id1 and Id2, concomitant with up-regulation of the basic helix-loop-helix factor Hxt and acquisition of increased adhesiveness. Endoreduplication disrupts the alternation of DNA synthesis and mitosis that maintains euploid DNA content during proliferation. To determine how the mammalian endocycle is regulated, we examined the expression of the cyclins and cyclin-dependent kinases during the transition from replication to endoreduplication in the Rcho-1 rat choriocarcinoma cell line. We cultured these cells under conditions that gave relatively synchronous endoreduplication. This allowed us to study the events that occur during the transition from the mitotic cycle to the first endocycle. With giant cell differentiation, the cells switched cyclin D isoform expression from D3 to D1 and altered several checkpoint functions, acquiring a relative insensitivity to DNA-damaging agents and a coincident serum independence. The initiation of S phase during endocycles appeared to involve cycles of synthesis of cyclins E and A, and termination of S was associated with abrupt loss of cyclin A and E. Both cyclins were absent from gap phase cells, suggesting that their degradation may be necessary to allow reinitiation of the endocycle. The arrest of the mitotic cycle at the onset of endoreduplication was associated with a failure to assemble cyclin B/p34(cdk1) complexes during the first endocycle. In subsequent endocycles, cyclin B expression was suppressed. Together these data suggest several points at which cell cycle regulation could be targeted to shift cells from a mitotic to an endoreduplicative cycle.     

decapentaplegic is required for arrest in G1 phase during Drosophila eye development

During eye development in Drosophila, cell cycle progression is coordinated with differentiation. Prior to differentiation, cells arrest in G1 phase anterior to and within the morphogenetic furrow. We show that Decapentaplegic (Dpp), a TGF-&bgr; family member, is required to establish this G1 arrest, since Dpp-unresponsive cells located in the anterior half of the morphogenetic furrow show ectopic S phases and ectopic expression of the cell cycle regulators Cyclins A, E and B. Conversely, ubiquitous over-expression of Dpp in the eye imaginal disc transiently inhibits S phase without affecting Cyclin E or Cyclin A abundance. This Dpp-mediated inhibition of S phase occurs independently of the Cyclin A inhibitor Roughex and of the expression of Dacapo, a Cyclin E-Cdk2 inhibitor. Furthermore, Dpp-signaling genes interact genetically with a hypomorphic cyclin E allele. Taken together our results suggest that Dpp acts to induce G1 arrest in the anterior part of the morphogenetic furrow by a novel inhibitory mechanism. In addition, our results provide evidence for a Dpp-independent mechanism that acts in the posterior part of the morphogenetic furrow to maintain G1 arrest.     

Cyclin D2 arrests Xenopus early embryonic cell cycles

Xenopus cyclin D2 mRNA is a member of the class of maternal RNAs. It is rare and stable during early embryonic development. To investigate the potential role of cyclin D2 during early embryonic cell cycles, cyclin D2 was injected into one blastomere of a two-cell embryo. This injection induced a cell cycle arrest in the injected blastomere. To analyze more precisely the mechanism of this arrest, we took advantage of cycling egg extracts that recapitulate major events of the cell cycle when supplemented with demembranated sperm heads. When Xenopus cyclin D2 is added to egg extracts, the first round of DNA replication occurs as in control extracts. However, Xenopus cyclin D2 blocks subsequent rounds of DNA replication and the oscillations of histone H1 kinase activity associated with cdc2 kinase, indicating that the cell cycle is arrested after the first S-phase. The block induced by Xenopus cyclin D2 is not due to a lack of the mitotic cyclin B2 that accumulates normally. Radiolabeled Xenopus cyclin D2 enters nuclei after completion of the first S-phase and remains stable over the entire period of the arrest. These features suggest that Xenopus cyclin D2 could play an original role during early development, controlling the G2-phase and/or the G2/M transition.     

Activation of the protein kinase p38 in the spindle assembly checkpoint and mitotic arrest

The mitogen-activated protein kinase (MAPK) superfamily comprises classical MAPK (also called ERK), c-Jun amino-terminal or stress-activated protein kinase (JNK or SAPK), and p38. Although MAPK is essential for meiotic processes in Xenopus oocytes and the spindle assembly checkpoint in Xenopus egg extracts, the role of members of the MAPK superfamily in M phase or the spindle assembly checkpoint during somatic cell cycles has not been elucidated. The kinase p38, but not MAPK or JNK, was activated in mammalian cultured cells when the cells were arrested in M phase by disruption of the spindle with nocodazole. Addition of activated recombinant p38 to Xenopus cell-free extracts caused arrest of the extracts in M phase, and injection of activated p38 into cleaving embryos induced mitotic arrest. Treatment of NIH 3T3 cells with a specific inhibitor of p38 suppressed activation of the checkpoint by nocodazole. Thus, p38 functions as a component of the spindle assembly checkpoint in somatic cell cycles.     

Drosophila myb is required for the G2/M transition and maintenance of diploidy

The myb proto-oncogenes are thought to have a role in the cell division cycle. We have examined this possibility by genetic analysis in Drosophila melanogaster, which possesses a single myb gene. We have described previously two temperature-sensitive, recessive lethal mutants in Drosophila myb (Dm myb). The phenotypes of these mutants revealed a requirement for myb in diverse cellular lineages throughout the course of Drosophila development. We now report a cellular explanation for these findings by showing that Dm myb is required for both mitosis and prevention of endoreduplication in wing cells. Myb apparently acts at or near the time of the G2/M transition. The two mutant alleles of Dm myb produce the same cellular phenotype, although the responsible mutations are located in different functional domains of the gene product. The mutant phenotype can be partially suppressed by ectopic expression of either cdc2 or string, two genes that are known to promote the transition from G2 to M. We conclude that Dm myb is required for completion of cell division and may serve two independent functions: promotion of mitosis, on the one hand, and prevention of endoreduplication when cells are arrested in G2, on the other.     

The coordination of centrosome reproduction with nuclear events of the cell cycle in the sea urchin zygote

Centrosomes repeatedly reproduce in sea urchin zygotes arrested in S phase, whether cyclin-dependent kinase 1-cyclin B (Cdk1-B) activity remains at prefertilization levels or rises to mitotic values. In contrast, when zygotes are arrested in mitosis using cyclin B Delta-90, anaphase occurs at the normal time, yet centrosomes do not reproduce. Together, these results reveal the cell cycle stage specificity for centrosome reproduction and demonstrate that neither the level nor the cycling of Cdk1-B activity coordinate centrosome reproduction with nuclear events. In addition, the proteolytic events of the metaphase-anaphase transition do not control when centrosomes duplicate. When we block protein synthesis at first prophase, the zygotes divide and arrest before second S phase. Both blastomeres contain just two complete centrosomes, which indicates that the cytoplasmic conditions between mitosis and S phase support centrosome reproduction. However, the fact that these daughter centrosomes do not reproduce again under such supportive conditions suggests that they are lacking a component required for reproduction. The repeated reproduction of centrosomes during S phase arrest points to the existence of a necessary "licensing" event that restores this component to daughter centrosomes during S phase, preparing them to reproduce in the next cell cycle.     

Control of division arrest and entry into meiosis by extracellular alkalisation in Saccharomyces cerevisiae

Limitation of nutrients allows yeast cells to arrest proliferation at G1 phase of the cell cycle and to enter the so-called stationary phase. We show here another pathway for cytostasis, which is associated with extracellular accumulation of bicarbonate and the resulting alkalisation of medium during the proliferation of cells respiring acetate. Alkalisation of medium by addition of bicarbonate or alkaline buffers ceased proliferation at G1 phase of logarithmically growing cells and caused a severe drop in G1-cyclin (CLN1 and CLN2) mRNAs. The arrested cells were heat-shock resistant, suggesting that the cells entered the stationary phase. Cells confluently grown on acetate re-entered into the cell cycle after acidification of the culture medium. These results indicate that external alkalisation is a primary cause of the cytostasis. The alkali-induced G1 arrest was shown to be cyclic AMP (cAMP)-independent using mutant cells which lack a functional Ras/cAMP signaling pathway. Alkalisation of medium also stimulated meiosis and sporulation in rich acetate medium, confirming our previous proposal that environmental alkalisation but not nitrogen limitation is a key condition for entry into meiosis and sporulation.     

Death activation does not stop tumor growth: quantitative evidence for concomitant activation of apoptosis in tumor growth in vitro

A protein-independent fibrosarcoma, Gc-4 PF, grows exponentially in a protein-free medium. The doubling time (approximately 26 h) was similar to that of the serum-dependent parental clone, Gc-4 SD cultivated in the presence of fetal calf serum (FCS). We demonstrated here that the protein-free cultivation of Gc-4 PF cells concomitantly activates apoptotic phenotypes (one third of total cell population), including typical morphology, high uptake of Hoechst 33342 dye, and cleavage of DNA to large fragments, as observed in protein-deprived Gc-4 SD cell previously. Gc-4 SD cells arrested in the G0/G1-phase in response to the protein-free condition. In contrast, Gc-4 PF cells did not reach G0/G1 arrest in the protein-free condition; instead the durations of both G0/G1 and G2-phases were markedly reduced. The estimation of one cell cycle duration revealed that the cell division cycle was accelerated to 1.7 (27 h/15.4 h)-fold. Then the growth kinetics was able to be verified quantitatively by both the cell division rate and apoptotic cell loss. Protein-free cultivation resulted in slight down-regulation of c-myc protein in both cell types, while the down-regulation of p34cdc2, shown clearly in Gc-4 SD cells, was avoided in Gc-4 PF cells. Interestingly, while the expression of p53 was not affected in Gc-4 SD cells in response to the protein-free condition, the suppressor gene product expression was suppressed markedly in Gc-4 PF cells. These results suggest that Gc-4 PF cells may have acquired an ability to accelerate cell division by shortening the cell cycle duration to maintain a proper growth rate in response to intrinsic apoptosis activation with, at least in part, a suppression of p53 expression as well as an escape of down-regulation of p34cdc2.     

Quantitative estimation of retinal nerve fiber layer height in glaucoma and the relationship with optic nerve head topography and visual field

During the evolution of normal cells into cancer cells, the occurrence of multiple mutations results in genetic instability. Mutations in DNA repair genes such as those of mismatch and excision repair predispose the carriers of these mutations to cancer by increasing the level of genomic instability. A variety of chromosome aberrations, such as abnormal ploidy, whole chromosome loss or chromosome amplification are commonly observed in cancer cells. From one cell division to the next, mammalian cells pass through an organized series of controlled events referred to as the cell cycle. In order to pursue an ordered series of molecular events, the initiation of an event during cell cycle progression is dependent on the successful completion of an earlier event. The cell cycle is divided into two major phases, namely, M(mitotic) phase and interphase. Interphase can be further divided into three distinct phases termed G1 (gap 1), S(DNA synthesis) and G2(gap2) phases (Fig. 1). Along with the machinery that promotes cell cycle progression, cells are also equipped with cell cycle checkpoints that ensure correct ordering of events in the cell cycle. The idea of "the cell cycle checkpoint" was first introduced by Hartwell and Weinert (1989) as "the arrest of a cell at a particular phase of the cycle due to a lack of appropriate signals for cell cycle progression". Until the checkpoint machinery receives the appropriate signal, the cell will not be allowed to make transition from one phase of the cell cycle to the next. Thus, the major role of checkpoint control is to minimize somatic genetic alterations and/or events affecting cellular survival. When one or more components of a cell cycle checkpoint are mutated, the chances of genetic instability during one round of the cell cycle increase accordingly with consequent acceleration of cellular evolution from the normal to the cancerous state. Therefore, mutations in checkpoint controls may predispose cells to cancer by causing genomic instability. In this review, I will focus on the potential roles of cell cycle checkpoints in the progression of malignancy.     

The Drosophila cell cycle gene fizzy is required for normal degradation of cyclins A and B during mitosis and has homology to the CDC20 gene of Saccharomyces cerevisiae

The Drosophila cell cycle gene fizzy (fzy) is required for normal execution of the metaphase-anaphase transition. We have cloned fzy, and confirmed this by P-element mediated germline transformation rescue. Sequence analysis predicts that fzy encodes a protein of 526 amino acids, the carboxy half of which has significant homology to the Saccharomyces cerevisiae cell cycle gene CDC20. A monoclonal antibody against fzy detects a single protein of the expected size, 59 kD, in embryonic extracts. In early embryos fzy is expressed in all proliferating tissues; in late embryos fzy expression declines in a tissue-specific manner correlated with cessation of cell division. During interphase fzy protein is present in the cytoplasm; while in mitosis fzy becomes ubiquitously distributed throughout the cell except for the area occupied by the chromosomes. The metaphase arrest phenotype caused by fzy mutations is associated with failure to degrade both mitotic cyclins A and B, and an enrichment of spindle microtubules at the expense of astral microtubules. Our data suggest that fzy function is required for normal cell cycle-regulated proteolysis that is necessary for successful progress through mitosis.     

CDK4 down-regulation induced by paclitaxel is associated with G1 arrest in gastric cancer cells

Paclitaxel induces a cell cycle block at G2-M phase by preventing the depolymerization of microtubules and induces p53-independent apoptosis in many cancer cells. We observed that gastric cancer cells treated with paclitaxel have shown a cyclin-dependent kinase (CDK)4 down-regulation. This paclitaxel-induced CDK4 down-regulation resulted in a cell cycle arrest at G1-S phase. To confirm this observation, we prepared stable transfectants that overexpressed CDK4 and analyzed the cell cycle progression. Ectopic expression of CDK4 in SNU cells resulted in a release of paclitaxel-induced G1 arrest. The release of G1 arrest by enforced expression of CDK4 seems to make the cells more sensitive to paclitaxel-induced apoptosis. From this finding, we could then suggest that paclitaxel treatment induces both G1-S and G2-M blocks in the cell cycle progression of gastric cancer cells.